Terms can be identified by their location. We note the 1st term in a sequence as a1 and we would call the 5th term in the sequence a5.

We described the pattern in the sequence as adding one to each term to get the next term. We can express this as a recursive formula by writing

an = an-1 + 1

This says to get any term in the sequence (an), add one (+1) to the previous term (an-1).

A recursive formula is written in such a way that in order to find any term in a sequence, you must know the previous terms. In other words, to find the 12th term, you would need to know the first 11. There are times when this can be a difficult task and there will be other ways to write sequences. But it is important to know that many sequences are best described using recursive formulas.

The simple sequence we have been looking at is called an arithmetic sequence. Any time you are adding the same number to each term to complete the sequence, it is called an arithmetic sequence. The number that is added to each term is called the common difference and denoted with the letter d. So in our example we would say that d = 1. The common difference can be subtracting two consecutive terms. You can subtract any two terms as long as they are consecutive. So we could find d by taking 5 - 4 = 1 or 2 - 1 = 1. Notice that we will always use the term that appears later in the sequence first and then subtract the term that is right in front of it.

If we looked at a sequence like bn = 1, 3, 9, 27, 81, 243, . . . this would not fit our definition of an arithmetic sequence. We are not adding the same number to each term. However, notice that we are multiplying each term by the same number (3) each time. When you multiply every term by the same number to get the next term in the sequence, you have a geometric sequence. Geometric sequences can also be written in recursive form. In this case, we would write . Remember that in the language of sequences we are saying, to find any term in the sequence (bn), multiply the previous term (bn-1) by 3.

Just as arithmetic sequences have a common difference, geometric sequences have a common ratio which is denoted with the letter r. The common ratio is found by dividing successive terms in the sequence. So in our geometric sequence example, we could use 9/3 = 3 or 243/81=3 to find that r = 3. As with finding a common difference, when we find a common ratio, we must use the term that appears later in the sequence as our numerator and the number right before it as our denominator.

There are other types of sequences that do not fit into the arithmetic or geometric category, but are still considered sequences because there is a pattern to determining the next term. Our focus in these lessons will be on arithmetic and geometric. For more information on other types of sequences, ask your teacher.

As mentioned earlier, recursive forms of sequences have their drawbacks, but are a useful way to see what is happening in a sequence. The other way to write sequences is called an explicit form or a closed form. These will be explored in other lessons.

Another topic associated with sequences is series. A series is simply adding the terms in a sequence. An arithmetic series involves adding the terms of an arithmetic sequence and a geometric series involves adding the terms of a geometric sequence. These will be explored in other lessons.

This lesson has provided an introduction to the terminology needed to continue working with sequences and series. One important skill is being able to identify what type of sequence you have. Do the “Try These” below and after successful completion of these problems, continue with other lessons on sequences and series.

Examples

Identify each sequence as arithmetic, geometric, or neither. If you identify it as arithmetic, specify d. If you identify it as geometric, specify r.